ObjectiveTo study the chemical constituents of Painong powder and the constituents absorbed into blood after oral administration to rats by ultra performance liquid chromatography-quadrupole-electrostatic field orbitrap high-resolution mass spectrometry （UPLC-Q-Orbitrap-MS）. MethodsUPLC-Q-Orbitrap-MS was employed for mass spectrometry data acquisition. The chemical constituents of Painong Powder and the constituents absorbed into blood were characterized and identified via Xcalibur 4.2 and Compound Discoverer v3.3.1 （CD） based on retention time， accurate molecular weights， secondary fragmentation ions， and comparison with reference standards and literature reports. ResultsA total of 176 chemical compounds， including 56 flavonoids， 42 triterpenoid saponins， 23 monoterpenes， 7 coumarins， 5 tannins， and other 43 compounds were identified from Painong powder. 49 components were identified in the rat plasma after oral administration of Painong powder， including 33 prototype constituents and 16 metabolites. The major metabolic pathways included hydrolysis in phase Ⅰ metabolic reactions， as well as methylation， sulfation， and glucuronidation in phase Ⅱ metabolic reaction. ConclusionThe method comprehensively identified the chemical constituents of Painong powder both in vitro and in vivo， and may provide a reference for the study of quality control and clinical applications.

Objective:To compare the efficacy and safety of robotic surgery and open surgery in the treatment of hilar cholangiocarcinoma.Methods:PubMed, Embase, Cochrane Library, Web of Science, CNKI and Wanfang database were searched to compare the treatment of hilar cholangiocarcinoma by robotic surgery and traditional open surgery. Literatures were searched from the establishment of the database to July 2023. Compare operation time, intraoperative blood transfusion rate, R 0 resection rate, lymph node metastasis rate, postoperative complication rate and hospital stays between the two groups. The combined odds ratio ( OR) and mean difference ( MD) and 95% confidence interval (95% CI) were calculated using RevMan 5.4 software. Results:A total of 4 studies were included, including 267 patients with hilar cholangiocarcinoma. There were 177 males and 90 females, aged (58.8±5.7) years. A total of 267 patients were divided into open surgery group ( n=165) and robotic surgery group ( n=102) according to the surgical formula. The extract results show: operative time ( MD=-103.96, 95% CI: -216.90-8.98, P=0.070) and intraoperative blood transfusion rate ( OR=1.32, 95% CI: 0.43-4.07, P=0.630), R 0 resection rate ( OR=1.41, 95% CI: 0.71-2.81, P=0.330), lymph node metastasis rate ( OR=1.62, 95% CI: 0.46-5.63, P=0.450), postoperative complications ( OR=0.60, 95% CI: 0.28-1.31, P=0.200), and postoperative hospital stay ( MD=2.17, 95% CI: -11.56-15.90, P=0.760). Conclusion:In the treatment of hilar cholangiocarcinoma, robotic surgery is as safe and feasible as open surgery. However, due to the limited number and quality of included studies, the above conclusions need to be verified by more high-quality studies.

Embryonic stem cells have remarkable proliferative and differentiation developmental capabilities and thus have great potential for cell therapy, disease modeling, and drug development. However, such totipotency has resulted in genomic instability, especially in the case of DNA damage. Human embryonic stem cells possess particular repair mechanisms to avoid the accumulation of such damage within the cell or its transmission to the offspring, thus ensuring the accuracy and safety of self-replication and differentiation development. This paper summarized the repair mechanisms of DNA damage in human embryonic stem cells and intends to provide a basis for further exploration of new ideas of stem cell therapy in conjunction with their repair mechanisms.

Embryonic stem cells have remarkable proliferative and differentiation developmental capabilities and thus have great potential for cell therapy, disease modeling, and drug development. However, such totipotency has resulted in genomic instability, especially in the case of DNA damage. Human embryonic stem cells possess particular repair mechanisms to avoid the accumulation of such damage within the cell or its transmission to the offspring, thus ensuring the accuracy and safety of self-replication and differentiation development. This paper summarized the repair mechanisms of DNA damage in human embryonic stem cells and intends to provide a basis for further exploration of new ideas of stem cell therapy in conjunction with their repair mechanisms.